U.S. patent application number 11/447496 was filed with the patent office on 2007-01-11 for intellingent three-way and four-way dimmers.
This patent application is currently assigned to Lutron Electronics Co., Inc.. Invention is credited to Steven E. Detmer, Jon M. Keagy, Donald Mosebrook, Christopher M. Rogan, Jamie J. Steffie.
Application Number | 20070007826 11/447496 |
Document ID | / |
Family ID | 36968771 |
Filed Date | 2007-01-11 |
United States Patent
Application |
20070007826 |
Kind Code |
A1 |
Mosebrook; Donald ; et
al. |
January 11, 2007 |
Intellingent three-way and four-way dimmers
Abstract
A smart dimmer switch for control of a lighting load from an AC
voltage source can replace any switch in a three-way or four-way
lighting control system. The smart dimmer switch can be connected
on the line-side or the load-side of a three-way system with a
standard three-way switch in the other location. Further, the
dimmer switch can replace a four-way switch in a four-way system
and is operable to be coupled to two standard three-way switches.
The dimmer switch includes either one or two semiconductor switches
to control the intensity of the connected lighting load. The dimmer
switch preferably includes a sensing circuit for detecting an
electrical characteristic (i.e., either a voltage or a current) at
a terminal of the dimmer to determine the state of the connected
three-way switch(s) or four-way switch. The dimmer switch
preferably controls the state of the semiconductor switch in
response to either a toggle of any of the other switches in the
system or an actuation of a toggle button of the dimmer switch.
Inventors: |
Mosebrook; Donald;
(Coopersburg, PA) ; Rogan; Christopher M.; (State
College, PA) ; Steffie; Jamie J.; (Slatington,
PA) ; Keagy; Jon M.; (Perkasie, PA) ; Detmer;
Steven E.; (Hellertown, PA) |
Correspondence
Address: |
OSTROLENK FABER GERB & SOFFEN
1180 AVENUE OF THE AMERICAS
NEW YORK
NY
100368403
US
|
Assignee: |
Lutron Electronics Co.,
Inc.
|
Family ID: |
36968771 |
Appl. No.: |
11/447496 |
Filed: |
June 6, 2006 |
Related U.S. Patent Documents
|
|
|
|
|
|
Application
Number |
Filing Date |
Patent Number |
|
|
60687690 |
Jun 6, 2005 |
|
|
|
Current U.S.
Class: |
307/139 |
Current CPC
Class: |
H05B 47/17 20200101;
H05B 47/185 20200101; H05B 47/165 20200101; H05B 39/041 20130101;
H05B 39/086 20130101; Y02B 20/40 20130101; Y02B 20/00 20130101;
H05B 39/08 20130101 |
Class at
Publication: |
307/139 |
International
Class: |
H01H 33/59 20060101
H01H033/59 |
Claims
1. A dimmer switch adapted to be coupled to a circuit including a
power source, a load, and a single-pole double-throw three-way
switch, the dimmer switch comprising: first, second, and third
electrical load terminals; a controllably conductive device
electrically coupled to the first, second, and third load
terminals, the controllably conductive device having a conductive
state in which the controllably conductive device is controlled so
as to deliver a desired amount of power to the load and a
non-conductive state in which the controllably conductive device is
controlled so as to deliver substantially no power to the load, the
controllably conductive device arranged such that when the
controllably conductive device is in the conductive state, and the
dimmer switch is coupled to the circuit, a current to the load
flows between the first terminal and the second terminal or between
the first terminal and the third terminal; a sensing device
electrically coupled to at least one of the second load terminal
and the third load terminal, the sensing device operable to sense
an electrical characteristic associated with the load terminal to
which the sensing device is coupled; a controller operably coupled
to the controllably conductive device and to the sensing device,
the controller operable to control the controllably conductive
device in response to an output of the sensing device in accordance
with the electrical characteristic; and a power supply electrically
coupled in shunt electrical connection with the controllably
conductive device and operable to provide power to the
controller.
2. The dimmer switch of claim 1, wherein the sensing device
comprises a current sensing device.
3. The dimmer switch of claim 2, wherein the current sensing device
comprises a current transformer.
4. The dimmer switch of claim 3, wherein the current transformer
comprises a primary winding and a secondary winding, the primary
winding of the current transformer being coupled between the
controllably conductive device and at least one of the second and
third load terminals, and the secondary winding of the current
transformer being coupled so as to provide the output of the
sensing device to the controller.
5. The dimmer switch of claim 4, wherein the current sensing device
is operable to detect whether a charging current is flowing in the
power supply.
6. The dimmer switch of claim 5, wherein the sensing circuit is
operable to generate a control signal representative of whether the
charging current is flowing in the power supply and the controller
is operable to change the controllably conductive device between
the conductive and non-conductive states in response to the control
signal.
7. The dimmer switch of claim 1, wherein the controllably
conductive device comprises a bidirectional semiconductor
switch.
8. The dimmer switch of claim 7, wherein the bidirectional
semiconductor switch comprises a triac.
9. The dimmer switch of claim 7, wherein the bidirectional
semiconductor switch comprises two field-effect transistors in
anti-series connection.
10. The dimmer switch of claim 1, further comprising: a
communication circuit adapted to receive a message including
control information; wherein the controller is operable to control
the controllably conductive device in dependence on the control
information.
11. The dimmer switch of claim 10, wherein the communication
circuit receives the message via an IR communication link.
12. The dimmer switch of claim 10, wherein the communication
circuit receives the message via an RF communication link.
13. The dimmer switch of claim 10, wherein the communication
circuit receives the message via a wired communication link.
14. The dimmer switch of claim 1, further comprising: a
communication circuit adapted to transmit a message including
feedback information representative of the state of the
controllably conductive device and the output of the sensing
device.
15. The dimmer switch of claim 14, wherein the communication
circuit transmits the message via an RF communication link.
16. The dimmer switch of claim 14, wherein the communication
circuit transmits the message via a wired communication link.
17. The dimmer switch of claim 1, further comprising: a memory
coupled to the controller.
18. The dimmer switch of claim 17, wherein the controller is
operable to store in the memory state information representative of
the state of the controllably conductive device and the output of
the sensing device.
19. The dimmer switch of claim 18, wherein the controller is
operable to recall the state information from the memory at power
up.
20. The dimmer switch of claim 1, further comprising: a visual
display for providing feedback to a user of the dimmer switch.
21. The dimmer switch of claim 20, wherein the visual display
comprises a plurality of light-emitting diodes.
22. The dimmer switch of claim 1, wherein the controller comprises
a microprocessor.
23. The dimmer switch of claim 1, further comprising: an actuator;
wherein the controller controls the controllably conductive device
in response to an actuation of the actuator.
24. The dimmer switch of claim 1, wherein the load comprises a
lighting load and the controller is operable to control the
conductive state of the controllably conductive device so as to
control a dimming level of the lighting load.
25. The dimmer switch of claim 1, further comprising: a fourth
electrical load terminal; and a second sensing device electrically
coupled to at least one of the first load terminal and the fourth
load terminal, the sensing device operable to sense a second
electrical characteristic associated with the load terminal to
which the second sensing device is coupled; wherein the controller
is coupled to the second sensing device and is operable to control
the controllably conductive device in response to an output of the
second sensing device in accordance with the second electrical
characteristic; and wherein the controllably conductive device is
arranged such that when the controllably conductive device is in
the conductive state and the dimmer switch is coupled to the
circuit, current to the load flows between the first load terminal
and one of the second load terminal and the third load terminal, or
between the fourth load terminal and one of the second load
terminal and the third load terminal, depending on the output of
the second sensing device.
26. A dimmer switch adapted to be coupled to a circuit including a
power source, a load, and a single-pole double-throw three-way
switch, the dimmer switch comprising: first, second, and third
electrical load terminals; a first controllably conductive device
having a conductive state in which the first controllably
conductive device is controlled so as to deliver a desired amount
of power to the load and a non-conductive state in which the
controllably conductive device is controlled so as to deliver
substantially no power to the load, the first controllably
conductive device electrically coupled between the first load
terminal and the second load terminal such that when the first
controllably conductive device is in the conductive state, and the
dimmer switch is coupled to the circuit, a current to the load
flows between the first load terminal and the second load terminal;
a second controllably conductive device having a conductive state
in which the second controllably conductive device is controlled so
as to deliver a desired amount of power to the load and a
non-conductive state in which the second controllably conductive
device is controlled so as to deliver substantially no power to the
load, the second controllably conductive device electrically
coupled between the first load terminal and the third load terminal
such that when the second controllably conductive device is in the
conductive state, and the dimmer switch is coupled to the circuit,
the current to the load flows between the first load terminal and
the third load terminal; a controller operably coupled to the first
and second controllably conductive devices and operable to cause
the first and second controllably conductive devices to be in one
of the conductive and non-conductive states; and a power supply
electrically coupled to the first, second, and third load terminals
and operable to provide power to the controller.
27. The dimmer switch of claim 26, further comprising: a first
sensing device electrically coupled to the second load terminal and
operable to sense a first electrical characteristic associated with
the second load terminal; and a second sensing device electrically
coupled to the third load terminal and operable to sense a second
electrical characteristic associated with the third load terminal;
wherein the controller is operable to control the first and second
controllably conductive devices in response to an output of the
first sensing device in accordance with the first electrical
characteristic and in response to an output of the second sensing
device in accordance with the second electrical characteristic.
28. The dimmer switch of claim 27, wherein the first sensing device
is coupled in shunt electrical connection with the first
controllably conductive device and the second sensing device is
coupled in shunt electrical connection with the second controllably
conductive device.
29. The dimmer switch of claim 28, wherein the first sensing device
comprises a first impedance coupled in series electrical connection
between the first load terminal and the second load terminal, and
the second sensing device comprises a second impedance coupled in
series electrical connection between the first load terminal and
the third load terminal; wherein the controller is responsive to a
first voltage produced across the first impedance and to a second
voltage produced across the second impedance.
30. The dimmer switch of claim 28, wherein the first sensing device
comprises a first optocoupler having an input photodiode coupled in
series electrical connection between the first load terminal and
the second load terminal, and the second sensing device comprises a
second optocoupler having an input photodiode coupled in series
electrical connection between the second load terminal and the
third load terminal; wherein the controller is responsive to an
output of the first optocoupler and an output of the second
optocoupler.
31. The dimmer switch of claim 27, wherein the first and second
sensing devices comprise current sensing devices.
32. The dimmer switch of claim 31, wherein the current sensing
devices comprise current transformers.
33. The dimmer switch of claim 27, further comprising: a
communication circuit adapted to transmit a message including
feedback information representative of the states of the first and
second controllably conductive devices and the outputs of the first
and second sensing devices.
34. The dimmer switch of claim 33, wherein the communication
circuit transmits the message via an RF communication link.
35. The dimmer switch of claim 33, wherein the communication
circuit transmits the message via a wired communication link.
36. The dimmer switch of claim 27, further comprising: a visual
display for providing feedback to a user of the dimmer switch.
37. The dimmer switch of claim 36, wherein the visual display
comprises a plurality of light-emitting diodes.
38. The dimmer switch of claim 27, wherein the controller is
operable to control both the first and second controllably
conductive devices to be simultaneously non-conductive so as to
deliver substantially no power to the load.
39. The dimmer switch of claim 26, further comprising: a
communication circuit adapted to receive a message including
control information; wherein the controller is operable to control
the first and second controllably conductive devices in dependence
on the control information.
40. The dimmer switch of claim 39, wherein the communication
circuit receives the message via an IR communication link.
41. The dimmer switch of claim 39, wherein the communication
circuit receives the message via an RF communication link.
42. The dimmer switch of claim 39, wherein the communication
circuit receives the message via a wired communication link.
43. The dimmer switch of claim 26, wherein the first and second
controllably conductive devices comprise bidirectional
semiconductor switches.
44. The dimmer switch of claim 43, wherein the bidirectional
semiconductor switches comprise triacs.
45. The dimmer switch of claim 43, wherein the bidirectional
semiconductor switches comprise two field-effect transistors in
anti-series connection.
46. The dimmer switch of claim 26, further comprising a memory
coupled to the controller.
47. The dimmer switch of claim 46, wherein the controller is
operable to store in the memory state information representative of
the states of the first and second controllably conductive
devices.
48. The dimmer switch of claim 47, wherein the controller is
operable to recall the state information from the memory at power
up.
49. The dimmer switch of claim 26, wherein the controller is
operable to control the first and second controllably conductive
devices to be conductive in a complementary basis, such that when
the first controllably conductive device is conductive, the second
controllably conductive device is non-conductive, and when the
second controllably conductive device is conductive, the first
controllably conductive device is non-conductive.
50. The dimmer switch of claim 26, wherein the controller comprises
a microprocessor.
51. The dimmer switch of claim 26, further comprising: an actuator;
wherein the controller controls the first and the second
controllably conductive devices in response to an actuation of the
actuator.
52. The dimmer switch of claim 26, wherein the load comprises a
lighting load and the controller is operable to control the
conductive states of the first and second controllably conductive
devices so as to control a dimming level of the lighting load.
53. The dimmer switch of claim 26, wherein the power supply is
coupled to the second terminal through a first diode and to the
third terminal through a second diode.
54. A dimmer switch adapted to be coupled to a circuit including a
power source, a load, a first single-pole double-throw switch, and
a second single-pole double-throw switch, the dimmer switch
comprising: first, second, third, and fourth electrical load
terminals; a controllably conductive device electrically coupled
between the first load terminal and the third load terminal for
carrying a load current to the load, the controllably conductive
device having a conductive state in which the controllably
conductive device is controlled so as to deliver a desired amount
of power to the load and a non-conductive state in which the
controllably conductive device is controlled so as to deliver
substantially no power to the load, the controllably conductive
device arranged such that when the controllably conductive device
is in the conductive state, and the dimmer switch is coupled to the
circuit, a current through the load flows from one of the first
load terminal and the second load terminal to one of the third load
terminal and the fourth load terminal; a first sensing device
electrically coupled between the first load terminal and the second
load terminal and adapted to carry the load current through the
second load terminal, the first sensing device operable to sense a
first electrical characteristic associated with the second load
terminal; a second sensing device electrically coupled between the
third load terminal and the fourth load terminal and adapted to
carry the load current through the fourth load terminal, the second
sensing device operable to sense a second electrical characteristic
associated with the fourth load terminal; a controller operably
coupled to the controllably conductive device and to the first and
second sensing devices, the controller operable to control the
controllably conductive device in response to an output of the
first sensing device and an output of the second sensing device;
and a power supply coupled in shunt electrical connection with the
controllably conductive device and operable to provide power to the
controller.
55. The dimmer switch of claim 54, wherein the first and second
sensing devices comprise current sensing devices.
56. The dimmer switch of claim 55, wherein the first sensing
circuit is operable to generate a first control signal
representative of whether a first current is flowing through the
first current sensing device, and the second sensing circuit is
operable to generate a second control signal representative of
whether a second current is flowing through the second current
sensing device; wherein the controller is operable to change the
controllably conductive device between the conductive and
non-conductive states in response to the first control signal and
the second control signal.
57. A dimmer switch adapted to be coupled to a circuit including a
power source having a hot connection and a neutral connection, a
load, and a single-pole double-throw three-way switch, the dimmer
switch comprising: first, second, and third electrical load
terminals; a controllably conductive device electrically coupled to
the first, second, and third load terminals, the controllably
conductive device having a conductive state in which the
controllably conductive device is controlled so as to deliver a
desired amount of power to the load and a non-conductive state in
which the controllably conductive device is controlled so as to
deliver substantially no power to the load, the controllably
conductive device arranged such that when the controllably
conductive device is in the conductive state and the dimmer switch
is coupled to the circuit, a current to the load flows between the
first load terminal and the second load terminal, or between the
first load terminal and the third load terminal; a sensing device
electrically coupled to at least one of the second load terminal
and the third load terminal, the sensing device operable to sense
electrical continuity between the hot connection and the neutral
connection of the power source through the controllably conductive
device and the load; a controller operably coupled to the
controllably conductive device and to the sensing device, the
controller operable to control the controllably conductive device
in response to an output of the sensing device; and a power supply
electrically coupled in shunt electrical connection with the
controllably conductive device and operable to provide power to the
controller.
58. A method for controlling a load in a circuit comprising a power
source, the load, a dimmer switch, and a single-pole double-throw
three-way switch, the method comprising the steps of: providing
first, second, and third electrical load terminals on the dimmer
switch; electrically coupling a controllably conductive device to
the first, second, and third load terminals, the controllably
conductive device having a conductive state in which the
controllably conductive device is controlled so as to deliver a
desired amount of power to the load and a non-conductive state in
which the controllably conductive device is controlled so as to
deliver substantially no power to the load; sensing an electrical
characteristic associated with at least one of the second load
terminal and the third load terminal; and controlling the
controllably conductive device in accordance with the sensed
electrical characteristic, such that a current through the load
flows between the first load terminal and the second load terminal,
or between the first load terminal and the third load terminal.
59. The method of claim 58, wherein the step of sensing comprises
sensing a current through one of the second load terminal and the
third load terminal.
60. The method of claim 59, further comprising the step of:
coupling a current transformer in series electrical connection with
at least one of the second load terminal and the third load
terminal.
61. The method of claim 60, further comprising the step of:
coupling a power supply in shunt electrical connection with the
controllably conductive device; wherein the step of sensing further
comprises detecting whether a charging current of the power supply
is flowing through the current transformer.
62. The method of claim 61, further comprising the step of:
generating a control signal representative of whether the charging
current is flowing through the current transformer; wherein the
step of controlling the controllably conductive device comprises
changing the controllably conductive device between the conductive
state and the non-conductive state in response to the control
signal.
63. The method of claim 58, wherein the controllably conductive
device comprises a bidirectional semiconductor switch.
64. The method of claim 63, wherein the bidirectional semiconductor
switch comprises a triac.
65. The method of claim 63, wherein the bidirectional semiconductor
switch comprises two field-effect transistors in anti-series
connection.
66. The method of claim 58, further comprising the step of:
receiving a message including control information; wherein the step
of controlling the controllably conductive device comprises
controlling the controllably conductive device in response to the
control information.
67. The method of claim 66, wherein the step of receiving the
message comprises receiving the message via an IR communication
link.
68. The method of claim 66, wherein the step of receiving the
message comprises receiving the message via an RF communication
link.
69. The method of claim 66, wherein the step of receiving the
message comprises receiving the message via a wired communication
link.
70. The method of claim 58, further comprising the step of:
transmitting a message including feedback information
representative of the state of the controllably conductive device
and a result of the step of sensing.
71. The method of claim 70, wherein the step of transmitting the
message comprises transmitting the message via an RF communication
link.
72. The method of claim 70, wherein the step of transmitting the
message comprises transmitting the message via a wired
communication link.
73. The method of claim 58, further comprising the step of: storing
in a memory state information representative of the state of the
controllably conductive device and the sensed electrical
characteristic.
74. The method of claim 73, further comprising the step of:
recalling the state information from the memory at power up.
75. The method of claim 58, further comprising the step of:
providing feedback to a user of the dimmer switch via a visual
display.
76. The method of claim 75, wherein the visual display comprises a
plurality of light-emitting diodes.
77. The method of claim 58, wherein the step of controlling the
controllably conductive device further comprises controlling the
controllably conductive device in response to an actuation of an
actuator of the dimmer switch.
78. The method of claim 58, wherein the load comprises a lighting
load and the step of controlling the controllably conductive device
further comprises controlling the conductive state of the
controllably conductive device so as to control a dimming level of
the load.
79. The method of claim 58, further comprising the steps of:
providing a fourth electrical load terminal on the dimmer switch;
and sensing a second electrical characteristic associated with at
least one of the first load terminal and the fourth load terminal;
wherein the step of controlling the controllably conductive device
further comprises controlling the controllably conductive device in
accordance with the sensed second electrical characteristic.
80. A method for controlling a load in a circuit comprising a power
source, the load, a dimmer switch, and a single-pole double-throw
three-way switch, the method comprising the steps of: providing
first, second, and third electrical load terminals on the dimmer
switch; electrically coupling a first controllably conductive
device between the first load terminal and the second load
terminal, the first controllably conductive device having a
conductive state in which the first controllably conductive device
is controlled so as to deliver a desired amount of power to the
load and a non-conductive state in which the controllably
conductive device is controlled so as to deliver substantially no
power to the load, the first controllably conductive device
arranged such that when the first controllably conductive device is
in the conductive state, a current through the load flows between
the first load terminal and the second load terminal; electrically
coupling a second controllably conductive device between the first
load terminal and the third load terminal, the second controllably
conductive device having a conductive state in which the second
controllably conductive device is controlled so as to deliver a
desired amount of power to the load and a non-conductive state in
which the second controllably conductive device is controlled so as
to deliver substantially no power to the load, the second
controllably conductive device arranged such that when the second
controllably conductive device is in the conductive state, the
current through the load flows between the first load terminal and
the third load terminal; and controlling the first and second
controllably conductive devices between the conductive state and
the non-conductive state.
81. The method of claim 80, further comprising the steps of:
sensing a first electrical characteristic associated with the
second load terminal; and sensing a second electrical
characteristic associated with the third load terminal; wherein the
step of controlling the first and second controllably conductive
devices comprises controlling the first and second controllably
conductive devices in accordance with the sensed first electrical
characteristic and the sensed second electrical characteristic.
82. The method of claim 81, further comprising the steps of:
coupling a first sensing device in shunt electrical connection with
the first controllably conductive device for sensing the first
electrical characteristic; and coupling a second sensing device in
shunt electrical connection with the second controllably conductive
device for sensing the second electrical characteristic.
83. The method of claim 82, wherein the first sensing device
comprises a first impedance coupled in series electrical connection
between the first load terminal and the second load terminal, and
the second sensing device comprises a second impedance coupled in
series electrical connection between the second load terminal and
the third load terminal; wherein the step of controlling the first
and second controllably conductive devices comprises controlling
the first and second controllably conductive devices in accordance
with a first voltage produced across the first impedance and a
second voltage produced across the second impedance.
84. The method of claim 82, wherein the first sensing device
comprises a first optocoupler having an input photodiode coupled in
series electrical connection between the first load terminal and
the second load terminal, and the second sensing device comprises a
second optocoupler having an input photodiode coupled in series
electrical connection between the second load terminal and the
third load terminal; wherein the step of controlling the first and
second controllably conductive devices comprises controlling the
first and second controllably conductive devices in accordance with
an output of the first optocoupler and an output of the second
optocoupler.
85. The method of claim 81, wherein the step of sensing a first
electrical characteristic comprises sensing a first current through
the second load terminal and the step of sensing a second
electrical characteristic comprises sensing a second current
through the third load terminal.
86. The method of claim 81, further comprising the step of:
transmitting a message including feedback information
representative of the states of the first and second controllably
conductive devices, the sensed first electrical characteristic, and
the sensed second electrical characteristic.
87. The method of claim 86, wherein the step of transmitting the
message comprises transmitting the message via an RF communication
link.
88. The method of claim 86, wherein the step of transmitting the
message comprises transmitting the message via a wired
communication link.
89. The method of claim 81, further comprising the step of:
providing feedback to a user of the dimmer switch via a visual
display.
90. The method of claim 89, wherein the visual display comprises a
plurality of light-emitting diodes.
91. The method of claim 81, wherein the step of controlling the
first and second controllably conductive devices comprises
controlling both the first and second controllably conductive
devices to be non-conductive so as to deliver substantially no
power to the load.
92. The method of claim 80, further comprising the step of:
receiving a message including control information; wherein the step
of controlling the first and second controllably conductive devices
comprises controlling the first and second controllably conductive
devices in accordance with the control information.
93. The method of claim 92, wherein the step of receiving the
message comprises receiving the message via an IR communication
link.
94. The method of claim 92, wherein the step of receiving the
message comprises receiving the message via an RF communication
link.
95. The method of claim 92, wherein the step of receiving the
message comprises receiving the message via a wired communication
link.
96. The method of claim 80, wherein the first and second
controllably conductive devices comprise bidirectional
semiconductor switches.
97. The dimmer switch of claim 96, wherein the bidirectional
semiconductor switches comprise triacs.
98. The dimmer switch of claim 96, wherein the bidirectional
semiconductor switches comprise two field-effect transistors in
anti-series connection.
99. The method of claim 81, further comprising the step of: storing
in a memory state information representative of the states of the
first and second controllably conductive devices, the sensed first
electrical characteristic, and the sensed second electrical
characteristic.
100. The method of claim 99, further comprising the step of:
recalling the state information from the memory at power up.
101. The method of claim 80, wherein the step of controlling the
first and second controllably conductive devices comprises
controlling the first and second controllably conductive devices to
be conductive in a complementary basis, such that when the first
controllably conductive device is conductive, the second
controllably conductive device is non-conductive, and when the
second controllably conductive device is conductive, the first
controllably conductive device is non-conductive.
102. The method of claim 80, wherein the step of controlling the
first and second controllably conductive devices further comprises
controlling the first and second controllably conductive devices in
response to an actuation of an actuator of the dimmer switch.
103. The method of claim 80, wherein the load comprises a lighting
load and the step of controlling the first and second controllably
conductive devices further comprises controlling the conductive
states of the first and second controllably conductive devices so
as to control a dimming level of the lighting load.
104. The method of claim 80, further comprising the step of:
coupling a power supply from the first load terminal to the second
load terminal through a first diode and to the third terminal
through a second diode.
105. A system for supplying power to a load from a power source
comprising: a single-pole double-throw (SPDT) three-way switch
comprising a first fixed contact, a second fixed contact, and a
movable contact adapted to be coupled to either the power source or
the load, the SPDT three-way switch having a first state in which
the movable contact is contacting the first fixed contact and a
second state in which the movable contact is contacting the second
fixed contact; and a dimmer switch comprising: a first load
terminal adapted to be coupled to either the power source or the
load to which the SPDT three-way switch is not coupled to; a second
load terminal coupled to the first fixed contact of the SPDT
three-way switch; a third load terminal coupled to the second fixed
contact of the SPDT three-way switch; a first controllably
conductive device electrically coupled such that when the first
controllably conductive device is in a conductive state, a desired
amount of power is capable of being delivered to the load, and when
the first controllably conductive device is in a non-conductive
state, substantially no power is capable of being delivered to the
load; a controller electrically coupled to the first controllably
conductive device and operable to control the first controllably
conductive device; and a power supply electrically coupled in shunt
electrical connection with the first controllably conductive device
and operable to provide power to the controller; wherein when the
SPDT three-way switch is in the first state, the controller is
operable to control the first controllably conductive device such
that a current to the load flows through the second load terminal
when the first controllably conductive device is in the conductive
state; and wherein when the SPDT three-way switch is in the second
state, the controller is operable to control the first controllably
conductive device such that the current to the load flows through
the third load terminal when the controllably conductive device is
in the conductive state.
106. The system of claim 105, wherein the first controllably
conductive device is electrically coupled between the first load
terminal and the second load terminal such that when the first
controllably conductive device is in the conductive state, a
current to the load flows between the first load terminal and the
second load terminal; wherein the dimmer switch further comprises a
second controllably conductive device having a conductive state in
which the second controllably conductive device is controlled such
that a desired amount of power is capable of being delivered to the
load and a non-conductive state in which the second controllably
conductive device is controlled such that substantially no power is
capable of being delivered to the load, the second controllably
conductive device electrically coupled between the first load
terminal and the third load terminal such that when the second
controllably conductive device is in the conductive state, current
to the load flows between the first load terminal and the third
load terminal.
107. The system of claim 106, wherein the dimmer switch further
comprises: a first sensing device electrically coupled to the
second load terminal and operable to sense a first electrical
characteristic associated with the second load terminal; and a
second sensing device electrically coupled to the third load
terminal and operable to sense a second electrical characteristic
associated with the third load terminal; wherein the controller is
operable to control the controllably conductive device in response
to an output of the first sensing device in accordance with the
first electrical characteristic and in response to an output of the
second sensing device in accordance with the second electrical
characteristic.
108. The system of claim 107, wherein the controller is operable to
determine whether the SPDT three-way switch is in the first state
or the second state in response to the outputs of the first and
second sensing devices.
109. The system of claim 108, wherein the dimmer switch further
comprises a memory coupled to the controller.
110. The system of claim 109, wherein the controller is operable to
store in the memory state information representative of the states
of the first and second controllably conductive devices and the
state of the SPDT three-way switch.
111. The system of claim 110, wherein the controller is operable to
recall the state information from the memory at power up.
112. The system of claim 108, wherein the dimmer switch further
comprises a communication circuit adapted to transmit a message
including feedback information representative of the states of the
first and second controllably conductive devices and the state of
the SPDT three-way switch.
113. The system of claim 108, wherein the load comprises a lighting
load and the dimmer switch further comprises a visual display for
providing to a user of the dimmer switch feedback information
representative of a dimming level of the lighting load, the
feedback information dependent on the states of the first and
second controllably conductive devices and the state of the SPDT
three-way switch.
114. The system of claim 107, wherein the controller is operable to
control both the first and second controllably conductive devices
to be non-conductive when the load is not powered.
115. The system of claim 106, wherein the first and second
controllably conductive devices comprise bidirectional
semiconductor switches.
116. The system of claim 106, wherein the dimmer switch further
comprises a communication circuit adapted to receive a message
including control information; and wherein the controller is
operable to control the first and second controllably conductive
devices dependent on the control information.
117. The system of claim 106, wherein the controller is operable to
control the first and second controllably conductive devices to be
conductive in a complementary basis, such that when the first
controllably conductive device is conductive, the second
controllably conductive device is non-conductive, and when the
second controllably conductive device is conductive, the first
controllably conductive device is non-conductive.
118. The system of claim 105, wherein the dimmer switch further
comprises a sensing device electrically coupled to at least one of
the second load terminal and the third load terminal, the sensing
device operable to sense an electrical characteristic associated
with the load terminal to which the sensing device is coupled;
wherein the first controllably conductive device is arranged such
that when the first controllably conductive device is in the
conductive state, a current to the load flows between the first
load terminal and the second load terminal, or between the first
load terminal and the third load terminal.
119. The system of claim 118, wherein the controller is operable to
determine whether the SPDT three-way switch is in the first state
or the second state in response to the output of the sensing
device.
120. The system of claim 119, wherein the sensing device comprises
a current sensing device.
121. The system of claim 120, wherein the current sensing device
comprises a current transformer.
122. The system of claim 119, wherein the dimmer switch further
comprises a memory coupled to the controller.
123. The system of claim 122, wherein the controller is operable to
store in the memory state information representative of the state
of the first controllably conductive device and the state of the
SPDT three-way switch.
124. The system of claim 123, wherein the controller is operable to
recall the state information from the memory at power up.
125. The system of claim 119, wherein the dimmer switch further
comprises a communication circuit adapted to transmit a message
including feedback information representative of the state of the
first controllably conductive device and the state of the SPDT
three-way switch.
126. The system of claim 119, wherein the load comprises a lighting
load and the dimmer switch further comprises a visual display for
providing to a user of the dimmer switch feedback information
representative of a dimming level of the lighting load, the
feedback information dependent on the state of the first
controllably conductive device and the state of the SPDT three-way
switch.
127. The system of claim 118, wherein the first controllably
conductive device comprises a bidirectional semiconductor
switch.
128. The system of claim 118, wherein the dimmer switch further
comprises a communication circuit adapted to receive a message
including control information; and wherein the controller is
operable to control the first controllably conductive device
dependent on the control information.
129. The system of claim 105, wherein the controller comprises a
microprocessor.
130. The system of claim 105, wherein the dimmer switch further
comprises an actuator; wherein an actuation of the actuator causes
the controller to control the first controllably conductive
device.
131. The system of claim 105, wherein the load comprises a lighting
load and the controller is operable to control the conductive state
of the first controllably conductive device so as to control a
dimming level of the lighting load.
132. The system of claim 105, wherein the first terminal of the
dimmer switch is coupled to the power source and the movable
contact of the SPDT three-way switch is coupled to the load.
133. The system of claim 105, wherein the first terminal of the
dimmer switch is coupled to the load and the movable contact of the
SPDT three-way switch is coupled to the power source.
134. A system for supplying power to a load from a power source
comprising: a first single-pole double-throw (SPDT) three-way
switch comprising a first fixed contact, a second fixed contact,
and a first movable contact adapted to be coupled to the power
source, the first SPDT three-way switch having a first state in
which the first movable contact is contacting the first fixed
contact and a second state in which the first movable contact is
contacting the second fixed contact; a second SPDT three-way switch
comprising a third fixed contact, a fourth fixed contact, and a
second movable contact adapted to be coupled to the load, the
second SPDT three-way switch having a third state in which the
second movable contact is contacting the third fixed contact and a
fourth state in which the second movable contact is contacting the
fourth fixed contact; and a dimmer switch comprising a first load
terminal coupled to the first fixed contact of the first SPDT
three-way switch, a second load terminal coupled to the second
fixed contact of the first SPDT three-way switch, a third load
terminal coupled to the third fixed contact of the second SPDT
three-way switch, and a fourth load terminal coupled to the fourth
fixed contact of the second SPDT three-way switch; wherein the
dimmer switch is operable to control the power delivered to the
load.
135. The system of claim 134, wherein the dimmer switch further
comprises: a controllably conductive device having a conductive
state in which the controllably conductive device is controlled
such that a desired amount of power is capable of being delivered
to the load and a non-conductive state in which the controllably
conductive device is controlled such that substantially no power is
capable of being delivered to the load; arranged such that when the
controllably conductive device is in the conductive state, a
current to the load flows between one of the first load terminal
and the second load terminal and one of the third load terminal and
the fourth load terminal; a first sensing device electrically
coupled to at least one of the first load terminal and the second
load terminal, the sensing device operable to sense a first
electrical characteristic associated with the load terminal to
which the first sensing device is coupled; a second sensing device
electrically coupled to at least one of the third load terminal and
the fourth load terminal, the sensing device operable to sense a
second electrical characteristic associated with the load terminal
to which the second sensing device is coupled; and a controller
electrically coupled to the controllably conductive device and
operable to control the controllably conductive device in response
to an output of the first sensing device and an output of the
second sensing device.
136. The system of claim 135, wherein the controller is operable to
determine whether the first SPDT three-way switch is in the first
state or the second state in response to the output of the first
sensing device and whether the second SPDT three-way switch is in
the third state or the fourth state in response to the output of
the second sensing device.
Description
RELATED APPLICATIONS
[0001] This application claims priority from commonly-assigned U.S.
Provisional Application Ser. No. 60/687,690, filed Jun. 6, 2005,
entitled INTELLIGENT THREE-WAY AND FOUR-WAY DIMMERS, the entire
disclosure of which is hereby incorporated by reference.
BACKGROUND OF THE INVENTION
[0002] 1. Field of the Invention
[0003] The present invention relates to dimmer switches for
electrical wiring systems having three-way switches. In particular,
the present invention relates to a dimmer switch that can be
substituted for a four-way switch, a line-side three-way switch, or
a load-side three-way switch in lighting circuits having either two
or more points of control, such as, for example, a four-way
system.
[0004] 2. Description of the Related Art
[0005] Three-way and four-way switch systems for use in controlling
loads in buildings, such as lighting loads, are known in the art.
Typically, the switches used in these systems are wired to the
building's alternating-current (AC) wiring system, are subjected to
AC source voltage, and carry full load current, as opposed to
low-voltage switch systems that operate at low voltage and low
current, and communicate digital commands (usually low-voltage
logic levels) to a remote controller that controls the level of AC
power delivered to the load in response to the commands. Thus, as
used herein, the terms "three-way switch", "three-way system",
"four-way switch", and "four-way system" mean such switches and
systems that are subjected to the AC source voltage and carry the
full load current.
[0006] A three-way switch derives its name from the fact that it
has three terminals and is more commonly known as a single-pole
double-throw (SPDT) switch, but will be referred to herein as a
"three-way switch". Note that in some countries a three-way switch
as described above is known as a "two-way switch".
[0007] A four-way switch is a double-pole double-throw (DPDT)
switch that is wired internally for polarity-reversal applications.
A four-way switch is commonly called an intermediate switch, but
will be referred to herein as a "four-way switch".
[0008] In a typical, prior art three-way switch system, two
three-way switches control a single load, and each switch is fully
operable to independently control the load, irrespective of the
status of the other switch. In such a system, one three-way switch
must be wired at the AC source side of the system (sometimes called
"line side"), and the other three-way switch must be wired at the
load side of the system.
[0009] FIG. 1A shows a standard three-way switch system 100, which
includes two three-way switches 102, 104. The switches 102, 104 are
connected between an AC voltage source 106 and a lighting load 108.
The three-way switches 102, 104 each include "movable" (or common)
contacts, which are electrically connected to the AC voltage source
106 and the lighting load 108, respectively. The three-way switches
102, 104 also each include two fixed contacts. When the movable
contacts are making contact with the upper fixed contacts, the
three-way switches 102, 104 are in position A in FIG. 1A. When the
movable contacts are making contact with the lower fixed contact,
the three-way switches 102, 104 are in position B. When the
three-way switches 102, 104 are both in position A (or both in
position B), the circuit of system 100 is complete and the lighting
load 108 is energized. When switch 102 is in position A and switch
104 is in position B (or vice versa), the circuit is not complete
and the lighting load 108 is not energized.
[0010] Three-way dimmer switches that replace three-way switches
are known in the art. An example of a three-way dimmer switch
system 150, including one prior art three-way dimmer switch 152 and
one three-way switch 104 is shown in FIG. 1B. The three-way dimmer
switch 152 includes a dimmer circuit 152A and a three-way switch
152B. A typical, AC phase-control dimmer circuit 152A regulates the
amount of energy supplied to the lighting load 108 by conducting
for some portion of each half-cycle of the AC waveform, and not
conducting for the remainder of the half-cycle. Because the dimmer
circuit 152A is in series with the lighting load 108, the longer
the dimmer circuit conducts, the more energy will be delivered to
the lighting load 108. Where the lighting load 108 is a lamp, the
more energy that is delivered to the lighting load 108, the greater
the light intensity level of the lamp. In a typical dimming
operation, a user may adjust a control to set the light intensity
level of the lamp to a desired light intensity level. The portion
of each half-cycle for which the dimmer conducts is based on the
selected light intensity level. The user is able to dim and toggle
the lighting load 108 from the three-way dimmer switch 152 and is
only able to toggle the lighting load from the three-way switch
104. Since two dimmer circuits cannot be wired in series, the
three-way dimmer switch system 150 can only include one three-way
dimmer switch 152, which can be located on either the line side or
the load side of the system.
[0011] A four-way switch system is required when there are more
than two switch locations from which to control the load. For
example, a four-way system requires two three-way switches and one
four-way switch, wired in well known fashion, so as to render each
switch fully operable to independently control the load
irrespective of the status of any other switches in the system. In
the four-way system, the four-way switch is required to be wired
between the two three-way switches in order for all switches to
operate independently, i.e., one three-way switch must be wired at
the AC source side of the system, the other three-way switch must
be wired at the load side of the system, and the four-way switch
must be electrically situated between the two three-way
switches.
[0012] FIG. 1C shows a prior art four-way switching system 180. The
system 180 includes two three-way switches 102, 104 and a four-way
switch 185. The four-way switch 185 has two states. In the first
state, node A1 is connected to node A2 and node B1 is connected to
node B2. When the four-way switch 185 is toggled, the switch
changes to the second state in which the paths are now crossed
(i.e., node A1 is connected to node B2 and node B1 is connected to
node A2). Note that a four-way switch can function as a three-way
switch if one terminal is simply not connected.
[0013] FIG. 1D shows another prior art switching system 190
containing a plurality of four-way switches 185. As shown, any
number of four-way switches can be included between the three-way
switches 102, 104 to enable multiple location control of the
lighting load 108.
[0014] Multiple location dimming systems employing a smart dimmer
switch and a specially designed remote (or "accessory") switch that
permit the dimming level to be adjusted from multiple locations
have been developed. A smart dimmer is one that includes a
microcontroller or other processing means for providing an advanced
set of control features and feedback options to the end user. For
example, the advanced features of a smart dimmer may include a
protected or locked lighting preset, fading, and double-tap to full
intensity. To power the microcontroller, smart dimmers include
power supplies, which draw a small amount of current through the
lighting load each half-cycle when the semiconductor switch is
non-conducting. The power supply typically uses this small amount
of current to charge a storage capacitor and develop a
direct-current (DC) voltage to power the microcontroller. An
example of a multiple location lighting control system, including a
wall-mountable smart dimmer switch and wall-mountable remote
switches for wiring at all locations of a multiple location dimming
system, is disclosed in commonly assigned U.S. Pat. No. 5,248,919,
issued on Sep. 28, 1993, entitled LIGHTING CONTROL DEVICE, which is
herein incorporated by reference in its entirety.
[0015] Referring again to the system 150 of FIG. 1B, since no load
current flows through the dimmer circuit 152A of the three-way
dimmer switch 152 when the circuit between the supply 106 and the
lighting load 108 is broken by either three-way switch 152B or 104,
the dimmer switch 152 is not able to include a power supply and a
microcontroller. Thus, the dimmer switch 152 is not able to provide
the advanced set of features of a smart dimmer to the end user.
[0016] FIG. 2 shows an example multiple location lighting control
system 200 including one wall-mountable smart dimmer switch 202 and
one wall-mountable remote switch 204. The dimmer switch 202 has a
Hot (H) terminal for receipt of an AC source voltage provided by an
AC power supply 206, and a Dimmed Hot (DH) terminal for providing a
dimmed-hot (or phase-controlled) voltage to a lighting load 208.
The remote switch 204 is connected in series with the DH terminal
of the dimmer switch 202 and the lighting load 208, and passes the
dimmed-hot voltage through to the lighting load 208.
[0017] The dimmer switch 202 and the remote switch 204 both have
actuators to allow for raising, lowering, and toggling on/off the
light intensity level of the lighting load 208. The dimmer switch
202 is responsive to actuation of any of these actuators to alter
the dimming level (or power the lighting load 208 on/off)
accordingly. In particular, actuation of an actuator at the remote
switch 204 causes an AC control signal, or partially rectified AC
control signal, to be communicated from that remote switch 204 to
the dimmer switch 202 over the wiring between the Accessory Dimmer
(AD) terminal of the remote switch 204 and the AD terminal of the
dimmer switch 202. The dimmer switch 202 is responsive to receipt
of the control signal to alter the dimming level or toggle the load
208 on/off. Thus, the load can be fully controlled from the remote
switch 204.
[0018] The user interface of the dimmer switch 202 of the multiple
location lighting control system 200 is shown in FIG. 3. As shown,
the dimmer switch 202 may include a faceplate 310, a bezel 312, an
intensity selection actuator 314 for selecting a desired level of
light intensity of a lighting load 208 controlled by the dimmer
switch 202, and a control switch actuator 316. The faceplate 310
need not be limited to any specific form, and is preferably of a
type adapted to be mounted to a conventional wall-box commonly used
in the installation of lighting control devices. Likewise, the
bezel 312 and the actuators 314, 316 are not limited to any
specific form, and may be of any suitable design that permits
manual actuation by a user.
[0019] An actuation of the upper portion 314A of the actuator 314
increases or raises the light intensity of the lighting load 208,
while an actuation of the lower portion 314B of the actuator 314
decreases or lowers the light intensity. The actuator 314 may
control a rocker switch, two separate push switches, or the like.
The actuator 316 may control a push switch, though the actuator 316
may be a touch-sensitive membrane. The actuators 314, 316 may be
linked to the corresponding switches in any convenient manner. The
switches controlled by actuators 314, 316 may be directly wired
into the control circuitry to be described below, or may be linked
by an extended wired link, infrared (IR) link, radio frequency (RF)
link, power line carrier (PLC) link, or otherwise to the control
circuitry.
[0020] The dimmer switch 202 may also include an intensity level
indicator in the form of a plurality of light sources 318, such as
light-emitting diodes (LEDs). Light sources 318 may be arranged in
an array (such as a linear array as shown) representative of a
range of light intensity levels of the lighting load 208 being
controlled. The intensity levels of the lighting load 208 may range
from a minimum intensity level, which is preferably the lowest
visible intensity, but which may be "full off", or zero, to a
maximum intensity level, which is typically "full on", or
substantially 100%. Light intensity level is typically expressed as
a percent of full intensity. Thus, when the lighting load 208 is
on, light intensity level may range from 1% to substantially
100%.
[0021] A simplified block diagram of the dimmer switch 202 and the
remote switch 204 of the multiple location lighting control system
200 is shown in FIG. 4. The dimmer switch 202 employs a
semiconductor switch 420 coupled between the hot terminal H and the
dimmed hot terminal DH, to control the current through, and thus
the light intensity of, the lighting load 208. The semiconductor
switch 420 may be implemented as a triac or two field effect
transistors (FETs) in anti-series connection. The semiconductor
switch 420 has a control input (or gate), which is connected to a
gate drive circuit 424. The input to the gate will render the
semiconductor switch 420 conductive or non-conductive, which in
turn controls the power supplied to the lighting load 208. The gate
drive circuit 424 provides control inputs to the semiconductor
switch 420 in response to command signals from a microcontroller
426.
[0022] The microcontroller 426 generates command signals to a
visual display, e.g., a plurality of LEDs 418, for feedback to the
user of the dimmer switch 202. The microcontroller 426 receives
inputs from a zero-crossing detector 430 and a signal detector 432.
A power supply 428 generates a DC output voltage V.sub.CC to power
the microcontroller 426. The power supply is coupled between the
hot terminal H and the dimmed hot terminal DH.
[0023] The zero-crossing detector 430 determines the zero-crossings
of the input AC waveform from the AC power supply 206. A
zero-crossing is defined as the time at which the AC supply voltage
transitions from positive to negative polarity, or from negative to
positive polarity, at the beginning of each half-cycle. The
zero-crossing information is provided as an input to
microcontroller 426. The microcontroller 426 provides the gate
control signals to operate the semiconductor switch 420 to provide
voltage from the AC power supply 206 to the lighting load 208 at
predetermined times relative to the zero-crossing points of the AC
waveform.
[0024] Generally, two techniques are used for controlling the power
supplied to the lighting load 208: forward phase control dimming
and reverse phase control dimming. In forward phase control
dimming, the semiconductor switch 420 is turned on at some point
within each AC line voltage half-cycle and remains on until the
next voltage zero-crossing. Forward phase control dimming is often
used to control energy to a resistive or inductive load, which may
include, for example, a magnetic low-voltage transformer or an
incandescent lamp. In reverse phase control dimming, the
semiconductor switch 420 is turned on at the zero-crossing of the
AC line voltage and turned off at some point within each half-cycle
of the AC line voltage. Reverse phase control is often used to
control energy to a capacitive load, which may include, for
example, an electronic low-voltage transformer. Since the
semiconductor switch 420 must be conductive at the beginning of the
half-cycle, and be able to be turned off with in the half-cycle,
reverse phase control dimming requires that the dimmer have two
FETs in anti-serial connection, or the like.
[0025] The signal detector 432 has an input 440 for receiving
switch closure signals from momentary switches T, R, and L. Switch
T corresponds to a toggle switch controlled by the switch actuator
316, and switches R and L correspond to the raise and lower
switches controlled by the upper portion 314A and the lower portion
314B, respectively, of the intensity selection actuator 314.
[0026] Closure of switch T will connect the input of the signal
detector 432 to the DH terminal of the dimmer switch 202, and will
allow both positive and negative half-cycles of the AC current to
flow through the signal detector. Closure of switches R and L will
also connect the input of the signal detector 432 to the DH
terminal. However, when switch R is closed, current can only flow
through the signal detector 432 during the positive half-cycle of
the AC power supply 406 because of a diode 434. In similar manner,
when switch L is closed, current can only flow through the signal
detector 432 during the negative half-cycles because of a diode
436. The signal detector 432 detects when the switches T, R, and L
are closed, and provides two separate output signals representative
of the state of the switches as inputs to the microcontroller 426.
A signal on the first output of the signal detector 432 indicates a
closure of switch R and a signal on the second output indicates a
closure of switch L. Simultaneous signals on both outputs
represents a closure of switch T. The microprocessor controller 426
determines the duration of closure in response to inputs from the
signal detector 432.
[0027] The remote switch 204 provides a means for controlling the
dimmer switch 202 from a remote location in a separate wall box.
The remote switch 204 includes a further set of momentary switches
T', R', and L' and diodes 434' and 436'. A wire connection is made
between the AD terminal of the remote switch 204 and the AD
terminal of the dimmer switch 202 to allow for the communication of
actuator presses at the remote switch. The AD terminal is connected
to the input 440 of the signal detector 432. The action of switches
T', R', and L' in the remote switch 204 corresponds to the action
of switches T, R, and L in the dimmer switch 202.
[0028] The system shown in FIGS. 2, 3, and 4 provides a fully
functional three-way switching system wherein the user is able to
access all functions, such as, for example, dimming at both
locations. However, in order to provide this functionality, both
switching devices need to be replaced with the respective devices
202, 204.
[0029] Sometimes it is desired to place only one smart switch in
the three-way or four-way switching circuit. As shown in FIG. 1B,
it is not possible heretofore to do this by simply replacing the
dimmer 152 with a smart dimmer, leaving mechanical three-way switch
104 in the circuit because when switch 104 breaks the circuit,
power no longer is provided to the microcontroller of the smart
dimmer (in place of the dimmer 152) because current no longer flows
through the dimmer to the lighting load 108. The three-way and
four-way dimmer switch according to the present invention provides
a solution to this problem and also optionally provides a means for
remote control of the switch.
[0030] In one prior art remote control lighting control system, a
single multi-location dimmer and up to nine "accessory" dimmers can
be installed on the same circuit to enable dimming from a plurality
of controls. In the prior art, accessory dimmers are necessary
because prior art multi-location dimmers are incompatible with
mechanical three-way switches. Accessory dimmers installed
throughout a house can greatly increase the cost of the components
and of the installation of a dimming system.
[0031] Moreover, even though the multiple location lighting control
system 200 allows for the use of a smart dimmer switch in a
three-way system, it is necessary for the customer to purchase the
remote switch 204 along with the smart dimmer switch 202. Often,
the typical customer is unaware that a remote switch is required
when buying a smart dimmer switch for a three-way or four-way
system until after the time of purchase when the smart dimmer
switch is installed and it is discovered that the smart dimmer
switch will not work properly with the existing mechanical
three-way or four-way switch. Therefore, there exists a need for a
smart dimmer that may be installed in any location of a three-way
or four-way system without the need to purchase and install a
special remote switch.
[0032] A smart three-way switch has also been designed that
operates with a conventional mechanical three-way switch, but that
system requires rewiring of the mechanical three-way switch in
order to provide proper three-way operation from both locations.
This is the subject of commonly assigned U.S. patent application
Ser. No. 11/125,045, filed May 9, 2005, entitled DIMMER FOR USE
WITH A THREE-WAY SWITCH, which is incorporated herein by reference
in its entirety.
SUMMARY OF THE INVENTION
[0033] The present invention improves upon these and other
shortcomings identified above, particularly with respect to the
existing smart three-way and four-way dimmer switches, providing
smart dimmer switches that can replace existing mechanical
three-way and four-way switches and being fully operational with
existing mechanical three-way and four-way switches without
requiring rewiring or replacement of the other switches.
[0034] According to one aspect, the invention comprises a dimmer
switch adapted to be coupled to a circuit including a power source,
a load, and a standard SPDT three-way switch. The dimmer switch
comprises first, second, and third electrical load terminals, and a
controllably conductive device electrically coupled to the first,
second, and third load terminals. The controllably conductive
device has a conductive state in which the controllably conductive
device is controlled such that a desired amount of power is
delivered to the load and a non-conductive state in which the
controllably conductive device is controlled such that
substantially no power is delivered to the load. The controllably
conductive device is arranged such that when the controllably
conductive device is in a conductive state, a current to the load
flows between the first terminal and the second terminal or between
the first terminal and the third terminal. The dimmer switch
further comprises a sensing device electrically coupled to at least
one of the second terminal and the third terminal and a controller
operably coupled to the controllably conductive device and to the
sensing device. The controller is operable to control the
controllably conductive device in response to an output of the
sensing device in accordance with an electrical characteristic. The
dimmer switch further comprises a power supply coupled in shunt
electrical connection with the controllably conductive device and
operable to provide power to the controller. In a preferred
embodiment, the sensing device comprises a current transformer for
sensing a current through one of the second load terminal and the
third load terminal.
[0035] According to another aspect, the invention comprises a
dimmer switch adapted to be coupled to a circuit including a power
source, a load, and a standard SPDT three-way switch, and
comprising a first controllably conductive device and a second
controllably conductive device. The dimmer switch also includes
first, second and third electrical load terminals, with the first
controllably conductive device electrically coupled between the
first load terminal and the second load terminal and the second
controllably conductive device coupled between the first and the
third load terminals. The first controllably conductive device is
arranged such that a current flows to the load between the first
load terminal and the second load terminal when the first
controllably conductive device is in the conductive state. The
second controllably conductive device is arranged such that a
current flows to the load between the first load terminal and the
third load terminal when the second controllably conductive device
is in the conductive state. The dimmer switch also includes a
controller electrically coupled to the controllably conductive
devices and operable to control the controllably conductive devices
between the conductive state and the non-conductive state, and a
power supply coupled to the first, second, and third load terminals
and operable to provide power to the controller. In a preferred
embodiment, the dimmer switch further comprises a first sensing
device and a second sensing device. The first sensing device is
electrically coupled to the second terminal and is operable to
sense a first electrical characteristic associated with the second
load terminal. The second sensing device is electrically coupled to
the third terminal and is operable to sense a second electrical
characteristic associated with the third load terminal. The
controller is further operable to control the first and second
controllably conductive devices in response to an output of the
first sensing device in accordance with the first electrical
characteristic and in response to an output of the second sensing
device in accordance with the second electrical characteristic.
[0036] According to yet another aspect, the invention comprises a
dimmer switch adapted to be coupled to a circuit including a power
source, a load, a first standard SPDT three-way switch, and a
second standard SPDT three-way switch. The dimmer switch comprises
first, second, third, and fourth electrical load terminals, and a
controllably conductive device electrically coupled between the
first load terminal and the third load terminal for carrying a load
current to the load. The controllably conductive device is arranged
such that when the controllably conductive device is in the
conductive state, a current to the load flows from one of the first
load terminal and the second load terminal to one of the third load
terminal and the fourth load terminal. The dimmer switch includes a
first sensing device electrically coupled between the first load
terminal and the second load terminal and adapted to carry the load
current through the second load terminal. The first sensing device
is operable to sense a first electrical characteristic associated
with the second load terminal. The dimmer switch includes a second
sensing device electrically coupled between the third load terminal
and the fourth load terminal and adapted to carry the load current
through the fourth load terminal. The second sensing device is
operable to sense a second electrical characteristic associated
with the fourth load terminal. The dimmer switch further includes a
controller operably coupled to the controllably conductive device
and to the first and second sensing devices. The controller is
operable to control the controllably conductive device in response
to an output of the first sensing device and an output of the
second sensing device. The dimmer switch also includes a power
supply coupled in shunt electrical connection with the controllably
conductive device to provide power to the controller.
[0037] According to yet another aspect of the present invention, a
dimmer switch comprises first, second, and third electrical load
terminals; a controllably conductive device electrically coupled to
the first, second, and third load terminals; a sensing device
electrically coupled to at least one of the second load terminal
and the third load terminal; a controller electrically coupled to
the controllably conductive device and to the sensing device; and a
power supply electrically coupled in shunt electrical connection
with the controllably conductive device and operable to provide
power to the controller. The controllably conductive device is
arranged such that when the controllably conductive device is in
the conductive state, a current to the load flows between the first
load terminal and the second load terminal, or between the first
load terminal and the third load terminal. The sensing device is
operable to sense continuity between the hot connection and the
neutral connection of the power source through the controllably
conductive device and the load. The controller is operable to
control the controllably conductive device in response to an output
of the sensing device.
[0038] The present invention further provides a method for
controlling a load in a circuit comprising a power source, the
load, a dimmer switch, and a standard SPDT three-way switch. The
method comprises the steps of providing first, second, and third
electrical load terminals on the dimmer switch, and electrically
coupling a controllably conductive device to the first, second, and
third load terminals. The controllably conductive device has a
conductive state in which the controllably conductive device is
controlled such that a desired amount of power is delivered to the
load and a non-conductive state in which the controllably
conductive device is controlled such that substantially no power is
delivered to the load. The method further comprises the steps of
sensing an electrical characteristic associated with at least one
of the second load terminal and the third load terminal, and
controlling the controllably conductive device in response to the
step of sensing in accordance with the electrical characteristic,
such that a current to the load flows between the first load
terminal and the second load terminal, or between the first load
terminal and the third load terminal. In a preferred embodiment,
the step of sensing comprises sensing a current through one of the
second load terminal and the third load terminal.
[0039] According to another aspect of the present invention, a
method for controlling a load comprises the steps of providing
first, second, and third electrical terminals, electrically
coupling a first controllably conductive device between the first
load terminal and the second load terminal, and electrically
coupling a second controllably conductive device between the first
load terminal and the third load terminal. The first controllably
conductive device is arranged such that when the first controllably
conductive device is in the conductive state, a current to the load
flows between the first load terminal and the second load terminal
and the second controllably conductive device is arranged such that
when the second controllably conductive device is in the conductive
state, the current to the load flows between the first load
terminal and the third load terminal. The method further comprises
the step of controlling the first and second controllably
conductive devices between the conductive state and the
non-conductive state. In a preferred embodiment the method further
comprises the steps of sensing a first electrical characteristic
associated with the second load terminal and sensing a second
electrical characteristic associated with the third load terminal.
Further, the step of controlling the first and second controllably
conductive devices comprises controlling the first and second
controllably conductive devices in response to the step of sensing
the first electrical characteristic and the step of sensing the
second electrical characteristic.
[0040] In addition, the present invention provides a system for
supplying power to a load from a power source. The system comprises
a standard single-pole double-throw (SPDT) three-way switch
comprising a first fixed contact, a second fixed contact, and a
movable contact adapted to be coupled to one of the power source
and the load. The SPDT three-way switch has a first state in which
the movable contact is contacting the first fixed contact and a
second state in which the movable contact is contacting the second
fixed contact. The system further comprises a dimmer switch
including a first load terminal adapted to be coupled to the one of
the power source and the load that the SPDT three-way switch is not
coupled to; a second load terminal coupled to the first fixed
contact of the SPDT three-way switch; a third load terminal coupled
to the second fixed contact of the SPDT three-way switch; a first
controllably conductive device electrically coupled such that when
the first controllably conductive device is in a conductive state,
a desired amount of power is operable to be delivered to the load,
and when the first controllably conductive device is in a
non-conductive state, substantially no power is operable to be
delivered to the load; a controller electrically coupled to the
first controllably conductive device and operable to control the
first controllably conductive device; and a power supply
electrically coupled in shunt electrical connection with the first
controllably conductive device and operable to provide power to the
controller. When the SPDT three-way switch is in the first state,
the controller is operable to control the first controllably
conductive device such that a current to the load flows through the
second load terminal. When the SPDT three-way switch is in the
second state, the controller is operable to control the first
controllably conductive device such that the current to the load
flows through the third load terminal.
[0041] According to a first embodiment of the system, the dimmer
switch further comprises a sensing device electrically coupled to
at least one of the second load terminal and the third load
terminal, the sensing device operable to sense an electrical
characteristic associated with the load terminal to which the
sensing device is coupled. The controller of the dimmer switch is
operable to determine the state of the SPDT three-way switch in
response to an output of the sensing device. According to a second
embodiment of the system, the dimmer switch further comprises a
second controllably conductive device; a first sensing device
electrically coupled to the second load terminal and operable to
sense a first electrical characteristic associated with the second
load terminal; and a second sensing device electrically coupled to
the third load terminal and operable to sense a second electrical
characteristic associated with the third load terminal. The
controller is operable to control the controllably conductive
device in response to an output of the first sensing device in
accordance with the first electrical characteristic and in response
to an output of the second sensing device in accordance with the
second electrical characteristic. The controller of the dimmer
switch is operable to determine the state of the SPDT three-way
switch in response to the outputs of the sensing devices.
[0042] According to yet another aspect, the present invention
provides a system for supplying power to a load from a power source
comprising a first standard single-pole double-throw (SPDT)
three-way switch, a second standard SPDT three-way switch, and a
dimmer switch. The first SPDT three-way switch comprises a first
fixed contact, a second fixed contact, and a first movable contact
adapted to be coupled to the power source. The first SPDT three-way
switch has a first state in which the first movable contact is
contacting the first fixed contact and a second state in which the
first movable contact is contacting the second fixed contact. The
second SPDT three-way switch comprises a third fixed contact, a
fourth fixed contact, and a second movable contact adapted to be
coupled to the load. The second SPDT three-way switch has a third
state in which the second movable contact is contacting the third
fixed contact and a fourth state in which the second movable
contact is contacting the fourth fixed contact. The dimmer switch
comprises a first load terminal coupled to the first fixed contact
of the first SPDT three-way switch, a second load terminal coupled
to the second fixed contact of the first SPDT three-way switch, a
third load terminal coupled to the third fixed contact of the
second SPDT three-way switch, and a fourth load terminal coupled to
the fourth fixed contact of the second SPDT three-way switch. The
dimmer switch is operable to control the power delivered to the
load.
[0043] Other features and advantages of the present invention will
become apparent from the following description of the invention
that refers to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0044] For the purpose of illustrating the invention, there is
shown in the drawings a form, which is presently preferred, it
being understood, however, that the invention is not limited to the
precise arrangements and instrumentalities shown. The features and
advantages of the present invention will become apparent from the
following description of the invention that refers to the
accompanying drawings, in which:
[0045] FIG. 1A shows a prior art three-way switch system, which
includes two three-way switches;
[0046] FIG. 1B shows an example of a prior art three-way dimmer
switch system including one prior art three-way dimmer switch and
one three-way switch;
[0047] FIG. 1C shows a prior art four-way switching system;
[0048] FIG. 1D shows a prior art extended four-way switching
system;
[0049] FIG. 2 is a simplified block diagram of a typical prior art
multiple location lighting control system;
[0050] FIG. 3 shows the prior art user interface of the dimmer
switch of the multiple location lighting control system of FIG.
2;
[0051] FIG. 4 is a simplified block diagram of the dimmer switch
and the remote switch of the prior art multiple location lighting
control system of FIG. 2;
[0052] FIG. 5A is a simplified block diagram of a three-way
lighting control system including a smart three-way dimmer
according to the present invention;
[0053] FIG. 5B shows a state diagram summarizing the operation of
the lighting control system of FIG. 5A;
[0054] FIG. 5C is a perspective view of a user interface of the
smart three-way dimmer of FIG. 5A;
[0055] FIG. 6A is a simplified block diagram of a three-way
lighting control system including a second embodiment of a smart
three-way dimmer according to the present invention;
[0056] FIG. 6B is a simplified schematic diagram of a first detect
circuit of the dimmer of FIG. 6A;
[0057] FIG. 7A is a simplified block diagram of a three-way
lighting control system including a third embodiment of a smart
three-way dimmer according to the present invention;
[0058] FIG. 7B shows a simplified schematic diagram of a current
detect circuit of the dimmer of FIG. 7A;
[0059] FIG. 8 is a simplified block diagram of a four-way lighting
control system including a smart four-way dimmer according to the
present invention;
[0060] FIG. 9 shows a state diagram summarizing the operation of
the lighting control system of FIG. 8;
[0061] FIG. 10 is a flowchart of a control loop of the controller
of the smart four-way dimmer of FIG. 8 for determining the state of
the dimmer;
[0062] FIG. 11 is a flowchart of the process of the button routine
of the control loop of FIG. 10;
[0063] FIG. 12 is a flowchart of the process of the current detect
routine of the control loop of FIG. 10;
[0064] FIG. 13 is a flowchart of the process of the triac state
routine of the control loop of FIG. 10; and
[0065] FIG. 14 is a flowchart of the startup process of the
controller of the dimmer switch of FIG. 8.
DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION
[0066] The foregoing summary, as well as the following detailed
description of the preferred embodiments, is better understood when
read in conjunction with the appended drawings. For the purposes of
illustrating the invention, there is shown in the drawings an
embodiment that is presently preferred, in which like numerals
represent similar parts throughout the several views of the
drawings, it being understood, however, that the invention is not
limited to the specific methods and instrumentalities
disclosed.
[0067] FIG. 5A is a simplified block diagram of a three-way
lighting control system 500 including a smart three-way dimmer
switch 502 according to the present invention. The dimmer 502 and a
standard three-way switch 504 are connected in series between an AC
voltage source 506 and a lighting load 508. The dimmer 502 includes
a hot terminal H that is coupled to the AC voltage source 506 and
two dimmed hot terminals DH1, DH2 that are connected to the two
fixed contacts of the three-way switch 504. The common terminal of
the three-way switch 504 is coupled to the lighting load 508.
Alternatively, the dimmer 502 could be connected on the load-side
of the system 500 with the three-way switch 504 on the line-side.
The dimmer 502 can be installed to replace an existing three-way
switch without the need to replace the other existing three-way
switch 504, and without the need for a wiring change to the
three-way switch being replaced. The terminals H, DH1, DH2 of the
dimmer 502 may be screw terminals, insulated wires or "flying
leads", stab-in terminals, or other suitable means of connecting
the dimmer to the AC voltage source 506 and the lighting load
508.
[0068] In this embodiment of the smart two-wire dimmer switch 502,
two bidirectional semiconductor switches 510, 514 are used. The
dimmer 502 implements each semiconductor switch as a triac.
However, other semiconductor switching circuits may be used, such
as, for example, two FETs in anti-series connection, or an
insulated-gate bipolar junction transistor (IGBT). A first triac
510 is connected in series between the hot terminal H and the first
dimmed hot terminal DH1. The first triac 510 has a gate (or control
input) that is coupled to a first gate drive circuit 512. A second
triac 514 is connected in series between the hot terminal H and the
second dimmed hot terminal DH2 and has a gate that is coupled to a
second gate drive circuit 516. The dimmer 502 further includes a
controller 518 that is coupled to the gate drive circuits 512, 516
to control the conduction times of the triacs 510, 514 each
half-cycle. The controller 518 is preferably implemented as a
microcontroller, but may be any suitable processing device, such as
a programmable logic device (PLD), a microprocessor, or an
application specific integrated circuit (ASIC).
[0069] A power supply 520 generates a DC voltage, V.sub.CC, to
power the controller 518. The power supply 520 is coupled from the
hot terminal H to the first dimmed hot terminal DH1 through a first
diode 522 and to the second dimmed hot terminal DH2 through a
second diode 524. This allows the power supply 520 to draw current
through the first dimmed hot terminal DH1 when the three-way switch
504 is in position A and through the second dimmed hot terminal DH2
when the three-way switch 504 is in position B. The power supply
520 is able to charge when the triacs 510, 514 are both not
conducting and there is a voltage potential developed across the
dimmer 520.
[0070] The dimmer 502 further includes a zero-crossing detector 526
that is also coupled between the hot terminal H and the dimmed hot
terminals DH1, DH2 through the diodes 522, 524, respectively. The
zero-crossing detector 526 provides a control signal to the
controller 518 that identifies the zero-crossings of the AC supply
voltage. The controller 518 determines when to turn on the triacs
510, 514 each half-cycle by timing from each zero-crossing of the
AC supply voltage.
[0071] A user interface 528 is coupled to the controller 518 and to
allow a user to determine a desired lighting level (or state) of
the lighting load 508. The user interface 528 provides a plurality
of actuators for receiving inputs from a user. For example, the
user interface 528 may comprise a toggle button 560 (i.e., a tap
switch) and an intensity actuator 570 (i.e., a slider control) as
shown in FIG. 5C. In response to an actuation of the toggle button
560, the controller 518 will toggle the state of the lighting load
508 (i.e., from on to off and vice versa) by changing which one of
the two triacs 510, 514 is conducting. The controller 518 drives
the triacs 510, 514 conduct on a complementary basis, such that
only one of the two triacs operable to conduct at a single time. In
this way, the dimmer 502 operates similarly to a standard SPDT
switch by allowing current to either flow through the first dimmed
hot terminal DH1 or the second dimmed hot terminal DH2 solely in
response to an actuation of the toggle button 560. Alternatively,
the user interface 528 may include a separate on button and off
button, which will cause the lighting load 508 to turn on and off,
respectively. Movement of the intensity actuator 570 will cause the
dimmer 502 to control the intensity of the lighting load 508. The
dimmer 502 further includes an airgap switch 530 for preventing
current flowing through either of the triacs 510, 514, and an
inductor 531 for providing electromagnetic interference (EMI)
filtering.
[0072] When the three-way switch 504 is in position A and the
desired state of the lighting load 508 is on, the controller 518
will turn the first triac 510 on for a portion of each half-cycle,
while maintaining the second triac 514 in the non-conducting state.
If the three-way switch 504 is then toggled from position A to
position B, current will not flow to the lighting load 508 since
the second triac 514 is not conducting. Therefore, the lighting
load 508 will not be illuminated. Alternatively, if the three-way
switch 504 is in position A, the lighting load 508 is on, and the
toggle button of the user interface 528 is actuated, the controller
518 will cause the first triac 510 to stop conducting and the
second triac 514 to begin conducting. The lighting load 508 will be
off because the controller 518 is driving the second triac 514
while the three-way switch 504 is in position A. If the toggle
button of the user interface 528 is actuated again, the controller
518 will stop driving the second triac 514 and will cause the first
triac 510 to begin conducting, thus causing the lighting load 508
to illuminate again.
[0073] Similarly, when the three-way switch 504 is in position B
and the desired state of the lighting load 508 is on, the
controller 518 will turn the second triac 514 on for a portion of
each half-cycle, while maintaining the first triac 510 in the
non-conducting state. If the three-way switch 504 is then switched
to position A, the current path to the lighting load 508 is
interrupted and the lighting load will be off. Also, if the
three-way switch 504 is in position B, the lighting load 508 is on,
and the toggle button of the user interface 528 is actuated, the
controller 528 will cause the second triac 514 to stop conducting
and the first triac 510 to begin conducting. The lighting load 508
will be off because the first triac 510 is conducting and the
three-way switch 504 is in position B.
[0074] The power supply 520 preferably has a large enough storage
capacitor to power the controller 518 during the times when the
three-way switch 504 is transitioning from position A to position B
and vice versa. For example, as the three-way switch 504 is
toggled, current temporarily will not flow through either of the
dimmed hot terminals DH1, DH2 as the movable contact transitions
and the power supply 520 will provide power to the controller 518
by virtue of the internal storage capacitor. The amount of power
that the power supply 504 needs to provide when the three-way
switch 504 is transitioning is dependent on the transitioning time
required for the movable contact to move from one fixed contact to
the other.
[0075] However, it is not always possible to guarantee that the
power supply 520 will be able to power the controller 518 and other
low voltage circuitry during the time when the three-way switch 504
is transitioning between positions. Because of space limitations in
a wall-mountable dimmer switch, it is not possible to simply
include a particularly large storage capacitor in the power supply
520 to provide power during the transitioning time. Also, since the
transitioning time is dependent on the force that a user exerts on
the actuator of the three-way switch 504, the transitioning time
can vary widely from one transition to the next. All three-way
switches 504 include a region of "dead travel", i.e., when the
movable contact of the three-way switch is approximately half way
between position A and position B and is not contacting either of
the fixed contacts. Sometimes, it is possible for the three-way
switch 504 to be sustained in the region of dead travel, such that
no current may flow through the power supply 520 for an
indeterminate period of time.
[0076] Accordingly, the dimmer 502 includes a memory 532 that
enables the dimmer 502 to return to the appropriate state, i.e., to
control the correct one of the two triacs 510, 514, if power to the
dimmer 502 is temporarily lost when the three-way switch 504 is
transitioning. The memory 532 is coupled to the controller 518.
Whenever the toggle button of the user interface 528 is actuated,
the controller 518 stores in the memory 532, which one of the
triacs 510, 514 is presently being controlled. In this way, if
dimmer 502 temporarily loses power and the DC voltage V.sub.CC
falls below a level that allows for proper operation of the
controller 518, the controller will read from the memory 532 which
triac 510, 514 to control at "power up", i.e. when the DC voltage
V.sub.CC rises back above the level that ensures proper operation
of the controller.
[0077] FIG. 5B shows a state diagram 550 summarizing the operation
of the lighting control system 500 of FIG. 5A. Two states 552, 554
are shown in which the lighting load 508 will be on since the
three-way switch 504 is in the correct position to complete the
circuit through the conducting triac. For example, at state 552,
when the three-way switch 504 is in position A, the first triac 510
is able to conduct current to thus control the lighting load 508.
The state diagram 550 also includes two states 556, 558 in which
the lighting load 508 will be off since the three-way switch 504 is
not in a position to conduct current through the triac that is
enabled for conduction. A transition between states can be caused
by one of three actions: a toggle of the three-way switch 504 from
position A to position B (designated by `B` in FIG. 5B), a toggle
of the three-way switch 504 from position B to position A
(designated by `A`), and an actuation of the toggle switch of the
user interface 528 (designated by `T`).
[0078] FIG. 6A shows a simplified block diagram of a three-way
lighting control system 600 including a second embodiment of a
smart three-way dimmer switch 602 according to the present
invention. A first detect circuit (or sensing circuit) 636 is
coupled across the first triac 510 and a second detect circuit (or
sensing circuit) 638 is coupled across the second triac 514. The
detect circuits 636, 638 provide control signals to the controller
618 representative of electrical characteristics of the first
dimmed hot terminal DH1 and the second dimmed hot terminal DH2,
respectively. Each of the electrical characteristics may be a
voltage developed across one of the respective triacs.
Alternatively, the detect circuits 636, 638 may be placed in series
with the dimmed hot terminals DH1, DH2 and the electrical
characteristics may be currents through the dimmed hot terminals.
In essence, the sensing of the electrical characteristics provides
a determination of whether a path of continuity exists between hot
and neutral of the AC voltage source 506 through the lighting load
508, the three-way switch 504, and the three-way dimmer switch 602,
at either the first dimmed hot terminal DH1 or the second dimmed
hot terminal DH2.
[0079] The controller 618 uses this information to determine the
position of the three-way switch 504 in the system 600. For
example, when the three-way switch 504 is in position A and the
first triac 510 is non-conductive, a voltage will develop across
the first detect circuit 636, which will output a signal indicating
that the three-way switch 504 is in position A. Similarly, when the
three-way switch 504 is in position B, the second detect circuit
638 will output a corresponding signal to the controller 618. The
controller 618 uses the information of the state of the three-way
switch 504 to provide feedback to the user via a plurality of LEDs
on a user interface 628 and may provide feedback information to
other control devices via an optional communication circuit 634.
For example, the user interface 628 may be the same as the user
interface shown in FIG. 3.
[0080] The communication circuit 634 may be coupled to a
communications link, for example, a wired serial control link, a
power-line carrier (PLC) communication link, or a wireless
communication link, such as an infrared (IR) or a radio frequency
(RF) communication link. An example of an RF lighting control
system is described in commonly assigned U.S. Pat. No. 5,905,442,
issued May 18, 1999, entitled METHOD AND APPARATUS FOR CONTROLLING
AND DETERMINING THE STATUS OF ELECTRICAL DEVICES FROM REMOTE
LOCATIONS.
[0081] Instead of providing complementary control of the triacs
510, 514, the controller 618 could control the triacs to the same
state at the same time. For example, when the first triac 510 is
conducting and the second voltage detect circuit 638 determines
that the three-way switch 504 has been toggled to position B, the
controller could cause both triacs to stop conducting since the
desired lighting level of the lighting load 508 is off. When
neither triac 510, 514 is conducting, substantially no power, i.e.,
only an amount of power that will not illuminate the lighting load
508, is conducted to the lighting load.
[0082] Accordingly, the controller is operable to detect a change
of the position of the three-way switch 504 and can determine when
to toggle power to the load based on the three-way switch position
change and the present state of the dimmer. Thus, the embodiments
shown in FIGS. 5A and 6A are compatible with a mechanical three-way
switch 504.
[0083] FIG. 6B is a simplified schematic diagram of a possible
implementation of the first detect circuit 636. Since the voltage
provided across the detect circuit 636 is an AC line voltage, the
detect circuit includes an optocoupler 640. A resistor 642 is
provided in series with the photodiodes 640A, 640B of the
optocoupler 640 to limit the current through the photodiodes. The
voltage at the collector of the phototransistor 640C of the
optocoupler 640 is provided to the controller 618. A resistor 646
is provided in series with the phototransistor 640C to pull the
voltage provided to the controller 618 up to the DC voltage VCC of
the power supply 520 when the phototransistor is not conducting
(i.e., when there is no voltage across the detect circuit 636).
[0084] When a voltage is produced across the detect circuit 636,
current flows through the photodiode 640A in the positive
half-cycles and the photodiode 640B in the negative half-cycles.
Hence, the phototransistor 640C conducts and the voltage at the
collector of the phototransistor is pulled down to a circuit common
648. The schematic diagram of the second detect circuit 638 is
identical to the schematic diagram of the first detect circuit 636
shown in FIG. 6B, differing only in the fact that the second detect
circuit 638 is connected between the hot terminal H and the second
dimmed hot terminal DH2. Alternatively, the first and second detect
circuits 636, 638 could be implemented as a simple resistive
circuit (not shown), for example, a resistor divider, with the
controller 518 operable to detect a voltage produced by the
resistive circuit.
[0085] FIG. 7A shows a simplified block diagram of a three-way
lighting control system 700 including a third embodiment of a smart
three-way dimmer switch 702 according to the present invention. In
this embodiment, the dimmer switch 702 includes a single
controllably conductive device, for example, a bidirectional
semiconductor switch, such as a triac 710. A controller 714 is
coupled to the gate of the triac 710 through a gate drive circuit
712 and controls the conduction time of the triac each half-cycle.
A power supply 716 is coupled across the triac 710 and generates a
DC voltage VCC to power the controller 714. A zero-crossing
detector 718 determines the zero-crossing points of the AC voltage
source 506 and provides this information to the controller 714. A
user interface 720 provides inputs to the controller 714 from a
plurality of buttons (including a toggle button) and includes a
plurality of LEDs for feedback to a user. A communication circuit
722 allows the controller 714 to transmit and receive messages with
other control devices. An airgap switch 724 disconnects the dimmer
switch 702 and the lighting load 508 from the AC voltage source
506. An inductor 725 is in series with the triac 710 and provides
EMI filtering. A memory 726 stores the present state of the dimmer
switch 702, such that the controller 714 can properly operate the
triac 710 at power up.
[0086] The dimmer 702 also includes a current detect circuit
(sensing circuit) 728 that is coupled between the first dimmed hot
terminal DH1 and the second dimmed hot terminal DH2. The current
detect circuit 728 is operable to detect when there is current
flowing through the second dimmed hot terminal DH2 and to
accordingly provide a control signal to the controller 714. The
power supply 716 provides a current path through the current detect
circuit 728 when the triac 710 is non-conducting. When the
three-way switch 504 is in position B, the charging current through
the power supply 716 will flow through the second dimmed hot
terminal DH2. The current detect circuit 728 will sense the
charging current and indicate to the controller 714 that the
three-way switch is in position B. When the three-way switch 504 is
in position A, no current will flow through the current detect
circuit 728 and no signal will be provided to the controller 714.
Thus, the controller 714 is able to determine the state of the
three-way switch 504 and to control the state of the lighting load
508 (i.e., on or off) accordingly.
[0087] The memory 726 stores the state of the triac 710 and of the
three-way switch 504. If the power supply 716 is unable to supply
power to the controller 714 through the duration of a transition of
the three-way switch 504, the controller 714 will reset, i.e.,
power down and then power up when the three-way switch 504 has
finished the transition. At power up, the controller 714 of the
dimmer 702 checks the status of the three-way switch 504 from the
control signal of the current detect circuit 728 and compares the
present state of the three-way switch to the state of the three-way
switch that is stored in the memory 726. If the status of the
three-way switch 504 has changed, the controller 714 will toggle
the state of the triac 710 based on the present state of the triac
that is stored in the memory 726.
[0088] FIG. 7B shows a simplified schematic diagram of the current
detect circuit (sensing circuit) 728 of the dimmer 702. The current
detect circuit 728 includes a current sense transformer 730 that
has a primary winding coupled in series between the dimmed hot
terminals DH1, DH2. The current sense transformer 730 only operates
above a minimum operating frequency, for example, 100 kHz, such
that current only flows in the secondary winding when the current
waveform through the primary winding has a frequency above the
minimum operating frequency. The current sense transformer 730
detects the falling edge of the current waveform through the power
supply 716 when the charging current flows through the second
dimmed hot terminal DH2. Since the dimmer 702 is using a triac as
the semiconductor switch, the dimmer operates using forward phase
control dimming, in which the triac 710 is non-conductive at the
beginning of each half-cycle. Thus, the power supply 716 charges at
the beginning of each half-cycle. When the power supply 716 stops
charging during a half-cycle, the charging current through the
power supply will drop to zero. Since the falling time of the
current waveform through the primary winding of the current sense
transformer 730 is very short (i.e., the waveform has a
high-frequency component), a current will flow in the secondary of
the current sense transformer when the switch 504 is in position B.
An example of the current sense transformer 730 is part number
CT319-200, manufactured by Datatronic, Ltd.
[0089] The secondary winding of the current sense transformer 730
is coupled across a resistor 732. The resistor 732 is further
coupled between circuit common and the negative input of a
comparator 734. A reference voltage is produced by a voltage
divider comprising two resistors 736, 738 and is provided to the
positive input of the comparator 734. The output of the comparator
734 is tied to V.sub.CC through a resistor 740 and is coupled to
the controller 714. When current flows through the secondary
winding of the current sense transformer 730, a voltage is produced
across the resistor 732 that exceeds the reference voltage. The
comparator 734 then drives the output low, signaling to the
controller 714 that current has been sensed. Alternatively, the
current detect circuit 728 may be implemented using an operational
amplifier or a discrete circuit comprising one or more transistors
rather than the comparator 734.
[0090] FIG. 8 is a simplified block diagram of a four-way lighting
control system 800 including a smart four-way dimmer switch 802
according to the present invention. The dimmer 802 and two
three-way switches 803, 804 are coupled between an AC voltage
source 806 and a lighting load 808. The dimmer 802 has replaced the
four-way switch 185 in the four-way lighting control system 180 of
FIG. 1C.
[0091] The dimmer 802 operates on the same principles as the dimmer
702 of FIG. 7A. However, the dimmer 802 includes an additional hot
terminal H2 that is coupled to the three-way switch 803 on the
line-side of the system 802. The dimmer 802 further comprises a
second current detect circuit (sensing circuit) 829 that is coupled
between the hot terminals H, H2 and provides a signal to a
controller 814. The second current detect circuit 829 operates in
the same manner as the first current detect circuit 728. When
current is detected flowing through the second current detect
circuit 829, the controller 814 determines that the line-side
three-way switch 803 is in position D. When no current is flowing
through the second current detect circuit 829, the three-way switch
803 is in position C. Thus, the controller 814 is able to determine
the states of both the line-side three-way switch 803 and the
load-side three-way switch 804 and to operate the triac 710
accordingly. When either three-way switch 803, 804 is toggled, or
the toggle button of the user interface 720 is actuated, the
controller 714 will toggle the state of the lighting load 808.
[0092] Even though the four-way dimmer switch 802 has four
connections, the dimmer could be installed in a three-way system
(in place of the three-way dimmer switch 502 in FIG. 5A or
three-way dimmer switch 702 in FIG. 7A). One of the additional
terminals DH2 or H2 would not be connected in the system 800. So,
the dimmer 802 allows for a single device that can be installed in
any location of a four-way or three-way system without the need to
determine in advance what kind of switch the dimmer will be
replacing.
[0093] FIG. 9 shows a state diagram 900 summarizing the operation
of the lighting control system 800 of FIG. 8. In four states 902,
904, 906, 908, the triac 710 will be conducting since the desired
state of the lighting load 808 is on. The state diagram 900 also
shows four states 912, 914, 916, 918 in which the desired state of
the lighting load 808 is off. A transition between states can be
caused by one of five actions: a toggle of the three-way switch 804
from position A to position B (designated by `B` in FIG. 6B), a
toggle of the three-way switch 804 from position B to position A
(designated by `A`), a toggle of the three-way switch 803 from
position C to position D (designated by `D`), a toggle of the
three-way switch 803 from position D to position C (designated by
`C`), and an actuation of the toggle switch of the user interface
720 (designated by `T`) (or when a "toggle" signal is received via
the communication circuit 722). Note that in all states of the
state diagram 900, the triac 710 is operable to conduct current to
the lighting load 808 to control the state of the lighting load
independent of the states of the three-way switches 803, 804.
[0094] The state diagram 900 thus identifies the status of the
three-way switch 803, the three-way switch 804, and the triac 710
(and thus the lighting load 808) for all possible states and shows
all the state transitions when the three-way switches 803, 804 are
toggled and the toggle button of the user interface 720 is actuated
(or when a "toggle" signal is received via the communication
circuit 722).
[0095] FIG. 10 is a flowchart of a state control procedure 1000 of
the controller 814 for determining the state of the dimmer 802. The
state control procedure 1000 runs periodically, for example,
approximately every 6 msec. The state control procedure 1000
includes a button routine 1100, a current detect routine 1200, and
a triac state routine 1300. While the button routine 1100, the
current detect routine 1200, and the triac state routine 1300 are
shown executing in sequential order in FIG. 10, these routines
alternatively could each be called from different pieces of
software and each be executed at a different interval.
[0096] The controller 814 utilizes a FIFO (first in, first out)
stack to store requests for the triac state routine 1300 to change
the state of the triac 710. The button routine 1100 and the current
detect routine 1200 are both operable to load an event (for
example, a "toggle event") into the FIFO stack. The triac state
routine loads these events from the FIFO stack and processes the
events. In the discussion of FIGS. 10 through 14, only toggle
events are discussed. However, other events, such as "increase
intensity" or "decrease intensity", could be loaded into the FIFO
stack by other routines (not described).
[0097] In the state control procedure 1000, the controller 814
utilizes three variables: TRIAC_STATUS, 1ST_DETECT, and 2ND_DETECT
that are stored in the memory 726. The variable TRIAC_STATUS stores
the conduction state of the triac 710, i.e., either ON or OFF. The
variables 1ST_DETECT and 2ST_DETECT store the state of the first
current detect circuit 728 and the second current detect circuit
829, respectively. The possible values for the variables 1ST_DETECT
and 2ST_DETECT are TRUE (when current is detected) and FALSE (when
current is not detected).
[0098] A flowchart describing the process of the button routine
1100 is shown in FIG. 11. At step 1110, the controller 814 first
checks the toggle button of the user interface 720. If the toggle
button is being pressed at step 1112, the controller 814 will load
a "toggle event" into the FIFO stack at step 1114 and exit the
process. If the toggle button is not being pressed at step 1112,
the process simply exits.
[0099] FIG. 12 is a flowchart of the process of the current detect
routine 1200. The outputs of the first current detect circuit 728
and second current detect circuit 829 are coupled to separate
interrupt inputs on the controller 814. Whenever an input is
provided from the first current detect circuit 728, a first
interrupt routine is executed to set a first current detect flag.
Similarly, whenever an input is provided from the first current
detect circuit 728, a second interrupt routine is executed to set a
second current detect flag.
[0100] Referring to FIG. 12, the first current detect flag is first
checked at step 1210. At step 1212, if the first current detect
flag has changed states, i.e., the new state of the first current
detect circuit is not equal to the value stored in the variable
1ST_DETECT, the process moves to step 1214, where a determination
is made as to whether the present value of the variable 1ST_DETECT
is equal to TRUE. If so, the variable 1ST_DETECT is set to FALSE at
step 1216; otherwise, the variable 1ST_DETECT is set to TRUE at
step 1218. Next, the controller 814 will load a "toggle event" into
the FIFO stack at step 1220.
[0101] After loading a toggle event into the FIFO stack at step
1220, or after detecting no change of state of the first current
detect circuit 728 at step 1212, the output of the second current
detect circuit 829 is checked at step 1222. At step 1224, if the
output of the second current detect circuit 829 has changed states,
i.e., the new state of the second current detect circuit is not
equal to the value stored in the variable 2ND_DETECT, a
determination is made as to whether the present value of the
variable 2ND_DETECT is equal to TRUE at step 1226. If so, the
variable 2ND_DETECT is set to FALSE at step 1228; otherwise, the
variable 2ND_DETECT is set to TRUE at step 1230. Next, the
controller 714 will load a toggle event into the FIFO stack at step
1232 and exit.
[0102] At step 1224, if the output of the second current detect
circuit 829 has not changed states, then the process simply exits
without loading a toggle event into the FIFO stack.
[0103] FIG. 13 is a flowchart of the process of the triac state
routine 1300. First, a toggle event is loaded from the FIFO stack
(and deleted from the stack at the same time) at step 1310. If
there is a toggle event in the FIFO stack to handle at step 1312,
the triac state will be toggled. At step 1314, if the variable
TRIAC_STATE is equal to OFF, then the variable TRIAC_STATE is set
to ON at step 1316. Otherwise, the variable TRIAC_STATE is set to
OFF at step 1318. At step 1320, the variables TRIAC_STATE,
1ST_DETECT, and 2ND_DETECT are stored in the memory 726. The
process loops until there are no toggle events to handle at step
1312, at which time the process exits.
[0104] FIG. 14 is a flowchart of the startup process 1400 that the
controller 814 performs at power up, for example, if the controller
814 loses power while a connected three-way or four-way switch is
transitioning. First, the controller 814 reads the variables
TRIAC_STATE, 1ST_DETECT, and 2ND_DETECT from the memory 726 at step
1410. Next, the controller 814 checks the status of the first
current detect circuit 728 and the second current detect circuit
829 in the current detect routine 1100. Next, the controller 814
determines whether to change the variable TRIAC_STATE in the triac
state routine 1200. Finally, the process exits to begin normal
operation executing the state control procedure 1000 of FIG.
10.
[0105] Although the embodiment of FIG. 8 shows two current detect
circuits 728, 829. Additional sensing circuits could be employed.
For example, a current detect circuit could be employed coupled in
series with each terminal of the smart four-way dimmer switch 802
for a total of four current detect circuits.
[0106] The smart dimmers 502, 602, 702, and 802 are useful in
three-way and four-way applications without the requirement of
replacing the standard switches already installed in the other
switching location(s). Unlike applications described above in the
prior art, all other switches at other switching locations in the
same three-way or four-way circuit do not have to be replaced with
an accessory dimmer. Accordingly, the present invention has a
reduced cost. Only one smart three-way or four-way dimmer need be
purchased and the existing switches in the three-way or four-way
switching circuit remain fully operational. By installing a single
dimmer 502, 602, 702, or 802, less time is required for
installation, thereby reducing installation costs. Also, there is
less chance of errors in installation (e.g., mistakes in wiring),
further reducing installation costs and the likelihood of damaging
and replacing units.
[0107] Thus, dimmers 502, 602, 702, and 802 are configurable as
three-way or four-way (or multi-way) switches that improve upon
prior art smart dimmers. In accordance with the present invention,
the dimmers are relatively inexpensive to manufacture, and are
easier to install in existing electrical systems than prior art
smart dimmers providing three-way and four-way switching
functionality. For example, users are not required to replace other
existing three-way switches with accessory dimmers. Moreover,
modifications to wiring of the other existing three-way switches is
avoided.
[0108] Furthermore, the various examples of three-way dimmers 502,
602, and 702 illustrated herein are each shown as connected
directly to the line-side of the lighting control systems. One of
ordinary skill in the art will recognize that, in the alternative,
the dimmers 502, 602, and 702 could be wired on the load-side of
the systems.
[0109] Although the words "device" and "unit" have been used to
describe the elements of the lighting control systems of the
present invention, it should be noted that each "device" and "unit"
described herein need not be fully contained in a single enclosure
or structure. For example, the dimmer 502 of FIG. 5 may comprise a
plurality of buttons in a wall-mounted enclosure and a controller
that is included in a separate location. Also, one "device" may be
contained in another "device". For example, the semiconductor
switch (i.e., the controllably conductive device) is a part of the
dimmer of the present invention.
[0110] Although the present invention has been described in
relation to particular embodiments thereof, many other variations
and modifications and other uses will become apparent to those
skilled in the art. Therefore, the present invention should not be
limited by the specific disclosure herein.
* * * * *